KR101271976B1 - Water-purifying cartridge and water purifier - Google Patents

Abstract

The water purification cartridge 6 forms a purification chamber S2 for purifying the introduced water and an additive storage chamber S1 for accommodating the additive 16 added to the introduced water. The case 7 provided with the 1st water tap 7a for introducing water into chamber S1 is provided. The additive storage chamber S1 forms an air storage region Aa where air collects in the upper part of the room when water is introduced, and a submerged region Aw where water introduced into the air storage region is accumulated. The additive 16 is submerged in the introduced water in the submerged region Aw. The additive 16 is accommodated in the additive storage chamber S1 from the portion to be the submerged region Aw to the portion to be the air storage region Aa. And the immersion height setting mechanism sets the immersion height of the immersion area | region Aw by setting the pressure of the air which gathered in the air storage area | region Aa. As the submerged height setting mechanism, a cap 28 having a through hole 28b serving as a fluid stop of the air discharge passage is provided.

Description

Water Purifier Cartridge and Water Purifier {WATER-PURIFYING CARTRIDGE AND WATER PURIFIER}

The present invention relates to a water purification cartridge and a water purifier using the water purification cartridge.

As a conventional water purifier, a plurality of water passages containing water lubricating agents having different mineral contents are provided, water passage control valves are provided in these passages, respectively, and water flow is controlled by controlling the opening and closing of each passage control valve. It is known to set the mineral concentration variable (patent document 1).

Japanese Patent Laid-Open No. 10-15564

However, in the conventional water purifier described in Patent Document 1, it is necessary to adjust a plurality of water passage control valves to set the mineral concentration of water. For this reason, there existed a problem that the setting work of adjusting several water flow control valves was cumbersome.

An object of the present invention is to provide a water purification cartridge which can more easily set an additive concentration of adding minerals to water, and a water purifier using the water purification cartridge.

The water purification cartridge according to the first technical feature of the present invention is provided with a purification chamber for purifying introduced water, and an additive receiving chamber for accommodating additives to be introduced into the water. It is provided with a case provided with a 1st tap for introducing. When the water is introduced into the room, the additive storage chamber forms an air storage region where air collects in the upper part of the room, and a submerged area where water introduced under the air storage area accumulates. The additive is submerged in the introduced water in the submerged zone. The said additive is accommodated in the said additive accommodation chamber from the part used as the said submerged area | region to the part used as the said air storage area | region. The immersion height setting mechanism sets the height of the immersion region by setting the pressure of air collected in the air storage region.

By such a configuration, by setting the pressure of the air collected in the air storage region by the immersion height setting mechanism, the immersion height in which the additive contained in the additive storage chamber is submerged can be set, and the additive concentration can be set accordingly. Therefore, in the purified water cartridge according to the first technical feature of the present invention, the additive concentration can be set more easily than in the conventional purified water cartridge which adjusts the opening and closing of a plurality of control valves and sets the additive concentration.

The water purification cartridge according to the first technical feature of the present invention may have a fluid stop provided in the air discharge passage for discharging air collected in the air storage region as the submersion height setting mechanism.

By this structure, a submerged height setting mechanism can be obtained as a simpler structure.

The water purification cartridge according to the first technical feature of the present invention may be provided with a valve in an air discharge passage through which air is discharged from the air storage region as the immersion height setting mechanism.

By such a configuration, it becomes easy to increase the pressure of air collected in the air storage region and to lower the height of the submerged region, so that the valve is easily provided to increase the flow resistance, so that the additive concentration can be set lower.

The water purification cartridge according to the first technical feature of the present invention may include an air pump for supplying air to the air storage region as the submersion height setting mechanism.

With such a configuration, as the air pump is provided, the pressure of the air collected in the air storage region can be further increased to make the height of the submerged region lower, and therefore the additive concentration can be set even lower. In addition, by controlling the air pump, the height of the submerged region can also be set more easily.

The water purification cartridge according to the first technical feature of the present invention may be provided with a second water hole in which the case bypasses the additive storage chamber and introduces water into the purification chamber.

With such a configuration, the flow rate of the water in the additive containing chamber is divided by dividing the water introduced from the first conduit and flowing through the additive containing chamber and the water introduced from the second conduit and bypassing the additive containing chamber. It becomes easy to adjust, and it becomes easy to raise the adjustment precision of additive concentration.

In addition, at this time, the first tap may be disposed above the second tap.

By such a structure, it can suppress that the flow volume of water in a tap, ie, the flow volume of water in an additive accommodating chamber, increases more than necessary by a head difference, the dynamic pressure of water, etc.

The water purifier according to the second technical feature of the present invention is a water purifier for purifying purified water by introducing water, wherein the water purifying cartridge according to the first technical feature of the present invention and a main body to which the water purifying cartridge is detachably mounted. It is provided.

With such a configuration, a water purifier equipped with a water purification cartridge having the same effects as described above can be obtained.

The water purifier according to the third technical feature of the present invention is a water purifier for purifying purified water by introducing water, and includes a purified water cartridge and a main body to which the purified water cartridge is detachably mounted. The water purification cartridge is provided with a purification chamber for purifying the introduced water therein and an additive receiving chamber for accommodating the additives added to the introduced water therein, and for introducing water into the additive receiving chamber. 1 case is provided with a raceway. When the water is introduced into the room, the additive storage chamber forms an air storage region where air collects in the upper part of the room, and a submerged area where water introduced under the air storage area accumulates. The additive is submerged in the introduced water in the submerged zone. The said additive is accommodated in the said additive accommodation chamber from the part used as the said submerged area | region to the part used as the said air storage area | region. The submerged height setting mechanism provided with the air pump which supplies air to the said air storage area | region is provided in the said main-body part. The immersion height setting mechanism sets the height of the immersion region by setting the pressure of air collected in the air storage region.

 By such a configuration, as the air pump is provided, the pressure of the air collected in the air storage region is further increased to make the immersion height lower, and therefore the additive concentration can be set even lower. In addition, by controlling the air pump, it is also possible to more easily set the height of the submerged region.

1 is a cross-sectional view of a water purifier according to Embodiment 1 of the present invention.
2 is a sectional view of a water purification cartridge according to Embodiment 1 of the present invention.
Fig. 3 is a sectional view of the water purification cartridge according to the first embodiment of the present invention, (a) is a view showing a state where a cap as a fluid diaphragm element having a relatively large flow resistance to air is installed, and (b) a flow flow resistance is relatively high. It is a figure which shows the state which attached the small cap.
4 is a sectional view of a water purification cartridge according to a second embodiment of the present invention.
5 is an enlarged view of a portion V of FIG. 4.
6 is a cross-sectional view of the water purifier according to the third embodiment of the present invention.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described in detail, referring drawings. In addition, the same component is included in several following examples. Therefore, below, the same code | symbol is attached | subjected to these same components, and the overlapping description is abbreviate | omitted.

Example 1

1 to 3 show Example 1 of the present invention.

First, with reference to FIG. 1, the schematic structure of the water purifier 1 which concerns on Example 1 is demonstrated. This water purifier 1 is configured as a port type water purifier. In the cylinder of the bottomed cylindrical port case 2, the bottomed cylindrical partition 3 is accommodated. And the cylinder of the port case 2 is partitioned by the partition 3 into the raw water chamber 4 which comprises about half of the upper side, and the water purification chamber 5 which forms about half of the lower side.

In the bottom wall 3a of the partition 3, a cylindrical recess 3b is formed which is recessed downward. The cylindrical water purification cartridge 6 is inserted into the recessed part 3b from the upper side to the inner side, and is fitted. An opening 3d is formed in the inner wall 3c of the recess 3b.

In the state where the purified water cartridge 6 is fitted into the recess 3b, the upper portion 6a of the purified water cartridge 6 is exposed in the raw water chamber 4. Then, in the upper portion 6a of the water purification cartridge 6, the first water tap 7a and the second water tap 7b formed in the case 7 face the raw water chamber 4. The second water hole 7b is provided near the bottom wall 3a. In this state, the lower end 6b of the purified water cartridge 6 is exposed into the purified water chamber 5 from the opening 3d. Then, at the lower end 6b of the water purification cartridge 6, the drain port 7c formed in the case 7 faces the water purification chamber 5. The raw water introduced into the raw water chamber 4 is introduced into the water purification cartridge 6 from the first water tap 7a and the second water tap 7b and at least purified, and then purified from the drain 7c. ) Is discharged as a purified water.

Above the raw water chamber 4, the ceiling wall 8 in which the water supply port 8a was formed is arrange | positioned. The water supply port 8a is closed by the upper opening lid 9 rotatably attached to the ceiling wall 8 so as to be openable and closed. Raw water is supplied into the raw water chamber 4 through the water supply port 8a in the state which opened the lid 9 upward.

In addition, a passage 10 extending from the water purification chamber 5 upward is formed between the side wall 3e of the partition 3 and the port case 2. In the pot case 2 or the ceiling wall 8, a water spout 10a is formed at a position that becomes the upper end of the passage 10. In Example 1, the pot case 2 is inclined to fall down so that the water inlet 10a can be lowered (in FIG. The stored purified water is discharged from the water inlet 10a via the passage 10. In addition, in Example 1, the spout 10a is closed by the upper opening lid 11 rotatably supported by the port case 2 or the ceiling wall 8 so that opening and closing is possible. In this case, when the port case 2 is inclined, the lid 11 can be rotated by its own weight, the dynamic pressure of water, or the like to open the water inlet 10a.

Next, with reference to FIG. 2, FIG. 3, the structure of the water purification cartridge 6 is demonstrated. The water purification cartridge 6 is formed in a cylindrical shape, and the cylindrical central axis Ax (see FIGS. 1 and 2) is used in a posture along the vertical direction. The case 7 has an upper case 12 which forms an upper part in the use state, and a lower case 13 which forms a lower part, and a lower edge and a lower case 13 of the upper case 12. The upper edges of are coupled to each other to show a cylindrical shape. In addition, below, the up-down direction, the axial direction, the circumferential direction, and the radial direction are prescribed | regulated on the basis of the cylindrical shape of the water purification cartridge 6 in a use state.

The case 7 is largely divided into three spaces in the up-down direction (axial direction) by the partition wall 14 and the sheet 15 disposed below the partition wall 14 at intervals. Among them, an additive accommodating chamber S1 in which the uppermost part accommodates the additive 16, a purifying chamber S2 in which the lowermost part purifies water, and an intermediate part S3.

The additive storage chamber S1 is formed surrounded by the upper case 12 and the partition wall 14. The upper case 12 is a water purification cartridge from the center portion of the circumferential wall 12a which forms the upper part of the circumferential wall of the case 7, the ceiling wall 12b which forms the ceiling wall of the case 7, and the ceiling wall 12b. It has an inner cylinder 12c which extends downward along approximately the central axis Ax of (6). And the partition 14 is attached to this upper case 12 so that the lower part in the cylinder may be blocked. That is, in Example 1, the additive storage chamber (A) is an annular cross-sectional space surrounded by the circumferential wall 12a, the ceiling wall 12b, the inner cylinder 12c, and the partition 14 in the cylinder of the upper case 12. S1) is formed. In this additive storage chamber S1, additives 16, such as particulate calcium of several millimeters in diameter, are accommodated, for example.

On the circumferential wall 12a, a substantially rectangular first raceway 7a is formed from the side. The water permeable mesh 17 is attached to this 1st water tap 7a by insert formation, etc., and the additive 16 is suppressed from overflowing from the 1st water tap 7a. In addition, the inner cylinder 12c is formed with a slit-shaped notch 12d extending upward from the lower end thereof. The width of the notches 12d is set smaller than the particle size of the additive 16. This suppresses the additive 16 from overflowing from the notch 12d. In addition, in Example 1, the position of the axial direction of the upper edge 12e of the notch 12d, and the position of the axial direction of the upper edge 12f of the 1st water tap 7a are made substantially the same.

Further, at the central portion of the bottom wall portion 14a of the partition 14, a protrusion 14b protruding conically toward the top is formed. In the center part of the projection part 14b, the cylinder part 14c which protrudes upwards and into which the inner cylinder 12c is inserted is formed. In the bottom wall portion 14a, a plurality of slits 14d extending radially from the central axis Ax of the water purification cartridge 6 are formed as drainage holes from the additive storage chamber S1. The width of the slit 14d is set smaller than the particle size of the additive 16, thereby suppressing the overflow of the additive 16 from the slit 14d.

In the additive storage chamber S1 having the above-described configuration, the additive 16 is added to the raw water introduced into the additive storage chamber S1 from the raw water chamber 4 through the first tap 7a or the second tap 7b. ) Elutes. Then, the added water of the additive flows out from the additive accommodation chamber S1 to the intermediate chamber S3 through the slit 14d of the partition wall 14.

Here, in Example 1, the air storage area | region Aa which traps air is formed in the upper part of additive accommodating chamber S1. Thereby, the additive 16 which exists in the air storage area | region Aa, ie, the upper part of the additive accommodating chamber S1, is not submerged. That is, the recessed part 18 which consists of the circumferential wall 12a, the ceiling wall 12b, and the inner cylinder 12c only opens downward, and there is no path from which air is discharged upward. For this reason, water penetrates into the additive storage chamber S1 from the first water hole 7a, and the upper portion 6a of the purified water cartridge 6 is completely submerged in the water stored in the raw water chamber 4 (that is, the number of water Even in this state), air is collected in the recess 18. Therefore, the blood of the additive 16 in the air storage region Aa can be prevented. That is, the additive 16 located below the upper limit L of the submerged region Aw is submerged in water, and the additive 16 located above the upper limit L is not submerged in water.

In such a configuration, when the additive 16 located below is immersed in water and eluted, the additive 16 located above drops downward by gravity, and is automatically supplied to the submerged region Aw. Therefore, the additive 16 accommodated in the additive accommodating chamber S1 can be used sequentially from the thing arrange | positioned below. For this reason, compared with the structure in which the additive contained in the purified water cartridge is flooded or avoided as a whole, the usable period of the additive 16 is easier to be taken, and the concentration of the additive in the initial use and the late use of the purified water cartridge 6 is longer. It becomes easy to suppress a difference smaller. Moreover, according to Example 1, the immersion height of the additive 16 can be set according to the height of the immersion area | region Aw, and, accordingly, the maximum value of an additive concentration can be set. That is, the additive 16 can be suppressed from dissolving in water more than necessary.

In the lower part of the circumferential wall 12a of the upper case 12 forming the circumferential wall of the intermediate chamber S3, a plurality of second water taps 7b are formed at substantially constant intervals in the circumferential direction. Therefore, the raw water is introduced into the intermediate chamber S3 from the raw water chamber 4 through the second tap 7b, and the added water of the additive is introduced from the additive storage chamber S1 through the slit 14d. do. And these water are introduce | transduced into the adsorption process chamber S21 (purification chamber S2) arrange | positioned under the intermediate chamber S3. That is, in Example 1, the raw water introduced into the intermediate chamber S3 from the second water hole 7b bypasses the additive containing chamber S1. Thus, by classifying the water flowing in the additive storage chamber S1 and the water bypassing the additive storage chamber S1, the flow rate of the water flowing in the additive storage chamber S1 and the additive storage chamber S1 are separated. The flow rate of the water to bypass can be set independently. For this reason, it becomes easy to raise the adjustment precision of additive concentration.

In addition, in Example 1, the 2nd water tap 7b is arrange | positioned below the 1st water tap 7a. For this reason, the head difference caused by the difference between the heights of the first raceway 7a and the second raceway 7b and the bottom wall 3a of the partition wall 3 are initially supplied to the raw water chamber 4. By the dynamic pressure of the water reaching the 2nd water tap 7b which is in the near position, water becomes more easy to enter into the 2nd water tap 7b compared with the 1st water tap 7a. Therefore, especially in the beginning supplied to the raw water chamber 4, the flow volume of the water in the 1st tap 7a can be made comparatively small, and it becomes easy to adjust the flow volume of the water in the additive accommodation chamber S1 small.

In addition, in Example 1, the additive accommodation chamber S1 is arrange | positioned above the 2nd water tap 7b. For this reason, after the water level of the raw water chamber 4 becomes lower than the lower end of the additive accommodating chamber S1, water will only flow in the purified water cartridge 6 from the 2nd water tap 7b. Therefore, the additive (in the intermediate chamber S3, the purification chamber S2, etc.) is downstream from the intermediate chamber S3 by water that does not pass through the additive storage chamber S1 and does not contain the additive 16. The discharge of 16 can be promoted to suppress the residual of the additive 16. Therefore, at the next use, the residual additive 16 suppresses the additive concentration from being higher than the set value, so that the desired additive concentration is easily obtained.

The purification | cleaning chamber S2 arrange | positioned under the intermediate chamber S3 is partitioned in the radial direction by the cylindrical cylinder 19 arrange | positioned at the position along the central axis Ax of the water purification cartridge 6. And in Example 1, the outer peripheral side of the cylinder 19 is made into the adsorption process chamber S21 in which the adsorbent (for example, granular or powdered activated carbon etc.) 20 was accommodated, and the inside of the cylinder of the cylinder 19 was a filter medium ( For example, it is set as the filtration process chamber S22 which accommodated the hollow fiber membrane etc. 21 curved in an inverted U shape. In such a configuration, the water introduced from the intermediate chamber S3 is discharged to the drain 7c of the lower end 6b via the adsorption treatment chamber S21 and the filtration treatment chamber S22 in this order. The cylinder body 19 is fitted into the recessed recessed part 13b which was formed in the center part of the bottom wall 13a of the lower case 13 which forms the bottom wall of the case 7. As shown in FIG. Thereby, the cylinder 19 is installed in the up-down direction along the central axis Ax of the water purification cartridge 6, and is installed.

The adsorption | suction process chamber S21 is surrounded by the circumferential wall 13c, the cylinder 19, the bottom wall 13a, and the sheet | seat 15 of the lower case 13 which form the lower part of the circumferential wall of the case 7, and is annular-shaped. It is formed in a cylindrical shape having a cross section of. The sheet 15 can be comprised, for example from a nonwoven fabric. In Example 1, the sheet | seat 15 is formed in ring shape, and surrounds the cylinder 19, and the outer edge part 15a is sandwiched between the upper case 12 and the lower case 13, It is fixed to the case 7. On the other hand, the inner edge 15b is a free end, so that water is introduced into the adsorption treatment chamber S21 from the intermediate chamber S3 via a gap between the inner edge 15b and the cylinder 19. Moreover, you may comprise the sheet | seat 15 with a water permeable material, and let water permeate. In addition, in Example 1, the cap 22 is attached to the upper end of the cylinder 19, and the inner edge part of the sheet | seat 15 is provided by the flange part 22a which protrudes outward from this cap 22 in diameter. 15b is prevented from being flipped back upward from the flange portion 22a. By this structure, even when the water purifying cartridge 6 is inclined or upside down in a state where the water purifying cartridge 6 is removed from the water purifier 1, the seat 15 is caught by the flange portion 22a to close the gap. For this reason, it can suppress that the adsorbent 20 leaks from the adsorption process chamber S21 to the intermediate chamber S3 side.

The communication port 19a is formed in the lower part of the cylinder 19. And the adsorption process chamber S21 and the filtration process chamber S22 are communicated with the communication port 19a. Water removed by adsorbing impurities to the adsorbent 20 in the adsorption treatment chamber S21 is introduced into the filtration treatment chamber S22 through the communication port 19a.

In the filtration processing chamber S22, many thin straw-shaped hollow fiber membranes as the filter medium 21 are housed in a state where they are bundled and curved in an inverted U shape. Water that has permeated through the membrane wall of the hollow fiber membrane from the filtration processing chamber S22 and flows into the membrane flows out into the lower end of the filtration processing chamber S22 through the membrane and flows out from the drain port 7c to the water purification chamber 5. When water passes through the membrane wall of the hollow fiber membrane, impurities contained in the water are filtered out. The hollow fiber membrane as the filter medium 21 is fixed to the cylinder 19 while the gap is filled with an adhesive (not shown) from the lower side of the communication port 19a, and is fixed from the inside of the filtration treatment chamber S22 by this adhesive. Direct outflow is prevented without passing through the hollow fiber membrane.

Moreover, if air collects unexpectedly in each part in the purified water cartridge 6, it will become impossible to obtain a desired flow volume, and it may take time until purified water is obtained, or a desired additive concentration may not be obtained. Here, in Example 1, the air discharge passage is formed substantially along the central axis Ax of the purified water cartridge 6.

Specifically, the circular through hole 12i communicating with the upper end side (inner side) of the inner cylinder 12c and the outside is formed in the center part of the ceiling wall 12b of the upper case 12, This through hole The cap 28 is fitted and fitted to block 12i. The cap 28 has a disk-shaped plate part 28a and a protrusion part 28c projecting upward from the peripheral edge part of the plate part 28a, and the through-hole 28b is formed in the center part of the plate part 28a. It is. In Example 1, this through hole 28b functions as an air discharge hole.

The cap 22 fitted to the upper end of the cylinder 19 has a conical portion 22b that tapers as it goes upward, and a cylindrical portion 22c that extends upward from the top of the cone portion 22b. The tip end of the cylindrical portion 22c is extended to the inside of the inner cylinder 12c. Therefore, the air in filtration processing chamber S22 is discharged | emitted from the through hole 28b through the inside of the cylinder part of the cone part 22b, the cylinder part 22c, and the inner cylinder 12c.

Air in the adsorption process chamber S21 and the intermediate chamber S3 moves to the central axis Ax side of the water purification cartridge 6 while rising along the protrusion 14b of the partition 14, and passes through the notch 12d. It enters in the cylinder of 12c, and is discharged | emitted to the through-hole 28b.

The air in the additive storage chamber S1 passes through the inside of the cylinder of the inner cylinder 12c from the notch 12d, except that the air is collected in the recess 18 (air storage region Aa). Is discharged.

And in Example 1, the immersion height setting mechanism which sets the immersion height D of the additive 16 in the immersion area | region Aw is provided by setting the pressure of the air in the air storage area | region Aa. In Example 1, the cap 28 which has the through hole 28b as an air discharge hole is used as a immersion height setting mechanism. That is, as described above, the through hole 28b is provided in the air discharge passage (the end of the air discharge passage in the first embodiment), and the air in the additive storage chamber S1 is also purified water cartridge through the air discharge passage. (6) It is configured to be discharged outside. For this reason, the larger the air flow resistance of the air in the through hole 28b, the higher the pressure of the air in the air storage region Aa on the upstream side, so that the lower limit of the air storage region Aa, that is, the submerged region ( By lowering the position of the upper limit L of Aw), the immersion height D of the additive 16 can be made low. The lower the immersion height D, the smaller the amount of the additive 16 to be submerged, so that the additive concentration is lower. In Example 1, the through hole 28b corresponds to a fluid stop. The through-hole 28b as a fluid stop is comprised as an orifice, a choke stop, etc., for example.

3 (a) shows a state in which only one through hole 28b is formed in the water purification cartridge 6, and a cap 28 having a relatively high airflow resistance is mounted. In addition, FIG.3 (b) has shown the state which attached the cap 28A with two through-holes 28b formed, and comparatively low air flow resistance.

Only one through hole 28b is formed in the cap 28. For this reason, in the state of FIG.3 (a), the flow resistance of the air in an air discharge passage becomes a comparatively high state. In this case, therefore, it is difficult for air to be discharged relatively, so that the internal pressure of the air storage region Aa becomes relatively high, and the lower limit of the air storage region Aa, that is, the position of the upper limit L of the submerged region Aw is relatively lower. As a result, the immersion height D of the additive 16 becomes relatively low. Therefore, in this case, the additive concentration is relatively low.

Two through-holes 28b are formed in the cap 28A. For this reason, in the state of FIG. 3 (b), the flow resistance of the air in the air discharge passage is in a relatively low state. In this case, therefore, air is relatively easily discharged, the internal pressure of the air storage region Aa is relatively high, and the lower limit of the air storage region Aa, that is, the position of the upper limit L of the submerged region Aw is relatively higher. As a result, the immersion height D of the additive 16 becomes relatively high. Therefore, in this case, the additive concentration becomes relatively high.

In addition, the flow resistance of the air discharge passage can be changed also in accordance with the hole diameter of the through hole 28b of the cap 28. In other words, increasing the hole diameter (using a cap having a large hole diameter of a through hole) lowers the flow resistance, or decreases the hole diameter (using a cap having a small hole diameter of a through hole) to increase the flow resistance. It is possible.

In addition, as shown in FIG. 3A, in Example 1, the upper limit L of the submerged region Aw can be maintained at the height at which the first water hole 7a is formed. This is because, when the mesh 17 having an appropriately sized gap (so-called mesh size) is attached to the first water hole 7a, the pressure of air inside the mesh 17 and the pressure of water outside the mesh 17 are meshed. Balanced across (17), the water stays within the gap of the mesh 17, the water exists outside the mesh 17, and the air exists inside the mesh 17, so that the mesh (17) is used as the boundary between air and water. In addition, below the upper limit L, water exists inside and outside the mesh 17, and water can flow through the gap of the mesh 17. As shown in FIG.

As described above, in the first embodiment, the air storage region Aa is formed in the upper portion of the additive storage chamber S1 and introduced in the submerged region Aw which is lower than the air storage region Aa. The additive 16 was immersed in water. In the additive storage chamber S1, the additive 16 is accommodated from the portion to be the submerged area Aw to the portion to be the air storage area Aa, and the additive 16 is contained in the air storage area Aa. It can be kept inundated or avoided. Then, when the additive 16 in the submerged area Aw is immersed in water and eluted, the additive 16 located above it falls downward by gravity to automatically replenish the submerged area Aw. Therefore, the additive 16 accommodated in the additive accommodation chamber S1 can be used sequentially from the thing arrange | positioned below. For this reason, compared with the structure in which the additive contained in the purified water cartridge is flooded or avoided as a whole, the usable period of the additive 16 is easier to be taken, and the concentration of the additive in the initial use and the late use of the purified water cartridge 6 is longer. It is easy to suppress the variation of.

And in Example 1, as an immersion height setting mechanism which sets the immersion height D of the additive 16 in the immersion area | region Aw by setting the pressure of the air gathered in the air storage area | region Aa, an air discharge passage Caps 28 and 28A having through holes 28b serving as the fluid stops are provided. Therefore, the internal pressure of the air storage region Aa is set by appropriately setting the specifications (size, length, etc.) of the through hole 28d, and, accordingly, the immersion height of the additive 16 in the submerged region Aw ( D) can be set. Therefore, compared with the structure which changes a flow volume by providing a valve etc., the structure which can set variable additive concentration can be obtained as a simpler structure. In addition, when calcium etc. are used as an additive, the hardness of water can be variably set.

In addition, in Example 1, the caps 28 and 28A as the immersion height setting mechanism are detachably attached to the upper case 12 (case 7). For this reason, the caps 28 and 28A with different flow resistance by the through-hole 28b are replaced easily, and the internal pressure of the air storage area | region Aa is variably set, and therefore the density | concentration of the additive 16 is variable. Can be set.

In addition, in Example 1, the case 7 is provided with the 2nd water tap 7b which bypasses the additive accommodating chamber S1 and introduces water into the purification chamber S2. For this reason, the flow volume of the water which flows in the additive accommodating chamber S1, and the additive accommodating chamber S1 are divided | segmented by classifying the water which passes the additive accommodating chamber S1, and the water which bypasses the additive accommodating chamber S1. The flow rate of the bypass water can be set independently. Therefore, it becomes easy to set the flow volume of the water in the additive accommodation chamber S1 to the value suitable for concentration adjustment, and it becomes easy to raise the adjustment precision of additive concentration.

In addition, in Example 1, the 1st water tap 7a was arrange | positioned above the 2nd water tap 7b. For this reason, the head difference caused by the difference between the heights of the first raceway 7a and the second raceway 7b and the bottom wall 3a of the partition wall 3 are initially supplied to the raw water chamber 4. By the dynamic pressure of the water reaching the 2nd water tap 7b which is in the near position, water becomes easier to enter from the 2nd water tap 7b compared with the 1st water tap 7a. Therefore, especially in the beginning supplied to the raw water chamber 4, the flow volume of the water in the 1st tap 7a can be made relatively small. For this reason, it is possible to suppress that the flow rate of water increases more than necessary in the additive accommodation chamber S1 and affects the concentration of the additive (the concentration increases or decreases).

Example 2

4 and 5 show Embodiment 2 of the present invention.

In Example 2, the cap 28B as a submersion height setting mechanism is attached to the purified water cartridge 6 according to the first embodiment in place of the caps 28 and 28A. The water purification cartridge 6 shown in FIG. 5 in which this cap 28B is attached can also be attached to the water purifier 1 shown in FIG.

The cap 28B is configured as a valve (one-way valve, check valve) that allows the flow of air from the bottom to the top and regulates the flow of air or water from the top to the bottom. The cap 28B has a through hole 28b and a valve body 29. And the valve body 29 is the structure which closes the through-hole 28b so that opening and closing is possible. The valve body 29 has a rod-shaped portion 29a fitted to the through hole 28d formed in the center portion of the plate portion 28a, and a plane spreading obliquely downward from the upper end portion of the rod-shaped portion 29a. The circular umbrella part 29b of a substantially circular shape is provided. The umbrella portion 29b covers the entirety of the plurality of through holes 28b from above. The bulging part 29c is formed in the front-end | tip part which escaped downward from the through-hole 28d of the rod-shaped part 29a. The bulging part 29c functions as a fall prevention of the rod-shaped part 29a. The valve body 29 is formed of a material having elasticity (flexibility), such as an elastomer. In the state in which the valve body 29 is attached to the plate portion 28a, the circumferential edge portion (tip edge) of the umbrella portion 29b is pressed against the plate portion 28a by the elasticity of the valve body 29, so that the seal is tight. It is supposed to be. That is, the upper surface of the plate part 28a functions as a valve seat, and the force pressurized by the plate part 28a becomes a preliminary load (set load).

That is, in Example 2, the pressure of the air of an upstream (namely lower side) is higher than the cap 28B, and it resists the preload of the valve body 29 (the umbrella part 29b of the valve body 29), and the said umbrella part 29b When is pushed up, the air is exhausted. Therefore, in Example 2, the internal pressure of the air storage area | region Aa becomes high by the preliminary load of this umbrella part 29b, and the lower limit of the air storage area | region Aa, namely, the upper limit L of the submerged area | region Aw. The position of becomes relatively downward. For this reason, the immersion height D of the additive 16 becomes comparatively low. Therefore, in this case, it becomes easy to set an additive concentration lower. Moreover, by setting the preload of the valve body 29, it becomes easy to set the internal pressure in air storage area | region Aa, and also an additive concentration more accurately.

Moreover, also in Example 2, the cap 28B as a submersion height setting mechanism is detachably attached to the upper case 12 (case 7). Therefore, it is comparatively easy that the preload of the valve body 29 differs. In other words, it is possible to variably set the internal pressure of the air storage region Aa and, therefore, vary the concentration of the additive 16.

Example 3

6 is a cross-sectional view of the water purifier according to the third embodiment of the present invention.

In Example 3, the water purifier 1C is provided with the pump unit 30 as an immersion height setting mechanism including the air pump 30p, and from this pump unit 30, through the pipe 30a, the water purification cartridge ( Air is supplied into the air storage region Aa of 6C).

Specifically, the shelf plate part 3f which protrudes toward the inside and becomes D-shaped in plan view is formed in the side wall 3e of the partition body 3 which forms a part of the main body part of the water purifier 1C. And the pump unit 30 is mounted and fixed on this shelf board part 3f. The lower end part of the piping 30a is inserted in the cylinder part 12j which protrudes downward from the ceiling wall 12b of the upper case 12C of the water purification cartridge 6, with the seal secured.

The pump unit 30 includes, for example, an air pump 30p constituted as a relatively small volumetric pump, an actuator such as a motor for driving the air pump 30p, a control valve for adjusting air pressure, and a predetermined pressure or more. Can be equipped with a relief valve that opens the pneumatic circuit, a pressure sensor, a timer, a control circuit that controls the operation of the motor or control valve, a power source such as a battery, an operation knob, a switch, and the like (except for the air pump 30p). Not).

In the purified water cartridge 6, a through hole 12k is formed in the upper end portion of the inner cylinder 12c as an air discharge hole.

In the above configuration, the concentration of the additive 16 can be variably set by varying the internal pressure of the air storage region Aa by the pump unit 30. In use, first, a user operates a switch or an operation knob to set whether the additive concentration is high or low. The pump unit 30 controls the pressure and the supply amount of air to be supplied in accordance with this setting. In the case where the additive concentration is set to be high, the pressure or the supply amount of the air to be supplied is controlled less. This lowers the internal pressure of the air storage region Aa, thereby lowering the position of the lower limit of the air storage region Aa, that is, the upper limit L of the submerged region Aw, and lowering the immersion height D of the additive 16. . On the contrary, when the additive concentration is set low, the pressure or the supply amount of the air to be supplied is controlled to be large. Thereby, the internal pressure of the air storage area Aa is raised to raise the position of the lower limit of the air storage area Aa, that is, the upper limit L of the submerged area Aw, thereby increasing the immersion height D of the additive 16. .

Moreover, the pressure of the air discharged from the air pump 30p is sufficient contact time with the adsorbent 20 filled in the purification chamber S2 in 6 C of purified water cartridges, when water passes through 6 C of purified water cartridges. It is desirable to set the pressure to a pressure capable of securing a flow rate and maintaining a flow rate capable of exhibiting purification performance.

In addition, in supplying air, based on the pressure detection result by a pressure sensor, you may feedback-control an air pump 30p and a control valve, or you may variably control pressure using an electromagnetic solenoid type control valve. In addition, the timer may control the period and timing of supplying air, or may turn off the power after a predetermined time elapses. In this case, the timing of turning off the power is that the treatment by the purified water cartridge 6C with respect to the total amount of water in the raw water chamber 4 is completed, and the discharge of water from the purified water cartridge 6C into the purified water chamber 5 is completed. It is suitable to be later than.

As described above, according to the third embodiment, as the pump unit 30 including the air pump 30p is provided, the pressure of the air collected in the air storage region Aa is further increased to make the immersion height D lower. Lose. For this reason, an additive concentration can be set still lower. In addition, by the control of the air pump 30p and others, the internal pressure of the air in the air storage region Aa can be controlled more easily and more precisely. For this reason, a desired additive concentration becomes easy to be obtained.

As mentioned above, although the suitable Example of this invention was described, this invention is not limited to the said Example, A various deformation | transformation is possible. For example, the purified water cartridge may have a shape other than a cylindrical shape, and the submerged height variable member may have a shape other than a bottomed cylindrical shape. In addition, an additive accommodation chamber, a purification chamber, a 1st water tap, a 2nd water tap, and other detailed specifications (shape, size, layout, accommodation, etc.) can also be changed suitably. Moreover, you may equip a water purification cartridge with the immersion height setting mechanism containing an air pump. In this case, the submerged height setting mechanism may be detachably attached to the purified water cartridge.

[Industrial applicability]

Industrial Applicability According to the present invention, it is possible to provide a water purification cartridge and a water purifier using the water purification cartridge, which can more easily set an additive concentration of adding minerals to water as compared with the conventional apparatus.

Claims (8)

As a clean water cartridge,
A purification chamber for purifying the introduced water and an additive receiving chamber for accommodating the additives added to the introduced water, and a first water outlet for introducing water into the additive receiving chamber; With one case,
The additive storage chamber forms an air storage region where air is collected at the upper part of the room when the water is introduced into the room, and a submerged area where water introduced at the bottom of the air storage area is collected.
The additive is submerged in the introduced water in the submerged region,
The said additive is accommodated in the said additive accommodation chamber from the part used as the said submerged area | region to the part used as the said air storage area | region,
A water purification cartridge, in which the immersion height setting mechanism sets the pressure of the air collected in the air storage region, thereby setting the height of the immersion region. The method according to claim 1,
The water immersion height setting mechanism has a fluid stop provided in an air discharge passage for discharging air collected in the air storage region. The method according to claim 1,
The water immersion height setting mechanism is a water purification cartridge, which is a valve provided in an air discharge passage through which air is discharged from the air storage region. The method according to claim 1,
The water immersion height setting mechanism includes an air pump for supplying air to the air storage region. The method according to claim 1,
The case further comprises a second water hole for bypassing the additive storage chamber and introducing water into the purification chamber. The method according to claim 5,
A water purification cartridge, wherein the first water hole is disposed above the second water hole. As a water purifier for obtaining purified water by introducing water,
With a clean water cartridge,
A water purifier having a main body to which the water purification cartridge is detachably mounted,
The water purification cartridge has a purging chamber for purifying the introduced water and an additive receiving chamber for accommodating the additives added to the introduced water, and a first tap for introducing water into the additive receiving chamber. Equipped with case,
The additive storage chamber forms an air storage region where air is collected at the upper part of the room when the water is introduced into the room, and a submerged area where water introduced at the bottom of the air storage area is collected.
The additive is submerged in the introduced water in the submerged region,
The said additive is accommodated in the said additive accommodation chamber from the part used as the said submerged area | region to the part used as the said air storage area | region,
A water purifier, in which the immersion height setting mechanism sets the height of the immersion region by setting the pressure of air collected in the air storage region. As a water purifier for obtaining purified water by introducing water,
With a clean water cartridge,
A main body to which the water purification cartridge is detachably mounted,
The water purification cartridge includes a purification chamber for purifying the introduced water and an additive receiving chamber for accommodating the additives added to the introduced water, and a first conduit for introducing water into the additive receiving chamber. With a case provided with
The additive storage chamber forms an air storage region where air is collected at the upper part of the room when the water is introduced into the room, and a submerged area where water introduced at the bottom of the air storage area is collected.
The additive is submerged in the introduced water in the submerged region,
The said additive is accommodated in the said additive accommodation chamber from the part used as the said submerged area | region to the part used as the said air storage area | region,
The main body is provided with a submersion height setting mechanism including an air pump for supplying air to the air storage region.
The water immersion height setting mechanism sets the height of the water immersion region by setting the pressure of air collected in the air storage region.

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